LINER LTC2282IUP-PBF

LTC2282
Dual 12-Bit, 105Msps
Low Power 3V ADC
FEATURES
DESCRIPTION
n
The LTC®2282 is a 12-bit 105Msps, low power dual 3V
A/D converter designed for digitizing high frequency,
wide dynamic range signals. The LTC2282 is perfect for
demanding imaging and communications applications
with AC performance that includes 70.1dB SNR and 85dB
SFDR for signals at the Nyquist frequency.
n
n
n
n
n
n
n
n
n
n
n
Integrated Dual 12-Bit ADCs
Sample Rate: 105Msps
Single 3V Supply (2.85V to 3.4V)
Low Power: 540mW
70.1dB SNR, 88dB SFDR
110dB Channel Isolation at 100MHz
Flexible Input: 1VP-P to 2VP-P Range
575MHz Full Power Bandwidth S/H
Clock Duty Cycle Stabilizer
Shutdown and Nap Modes
Pin Compatible Family
105Msps: LTC2282 (12-Bit), LTC2284 (14-Bit)
80Msps: LTC2294 (12-Bit), LTC2299 (14-Bit)
65Msps: LTC2293 (12-Bit), LTC2298 (14-Bit)
40Msps: LTC2292 (12-Bit), LTC2297 (14-Bit)
25Msps: LTC2291 (12-Bit), LTC2296 (14-Bit)
10Msps: LTC2290 (12-Bit), LTC2295 (14-Bit)
64-Pin (9mm × 9mm) QFN Package
DC specs include ±0.4LSB INL (typ), ±0.2LSB DNL (typ)
and no missing codes over temperature. The transition
noise is a low 0.3LSBRMS.
A single 3V supply allows low power operation. A separate
output supply allows the outputs to drive 0.5V to 3.6V
logic.
A single-ended CLK input controls converter operation. An
optional clock duty cycle stabilizer allows high performance
at full speed for a wide range of clock duty cycles.
, LT, LTC and LTM are registered trademarks of Linear Technology Corporation.
All other trademarks are the property of their respective owners.
APPLICATIONS
n
n
n
n
Wireless and Wired Broadband Communication
Imaging Systems
Spectral Analysis
Portable Instrumentation
TYPICAL APPLICATION
ANALOG
INPUT A
INPUT
S/H
–
CLK A
12-BIT
PIPELINED
ADC CORE
OUTPUT
DRIVERS
D11A
73
••
•
D0A
72
OGND
71
CLOCK/DUTY CYCLE
CONTROL
MUX
CLK B
SNR vs Input Frequency,
–1dB, 2V Range
OVDD
CLOCK/DUTY CYCLE
CONTROL
SNR (dBFS)
+
70
69
68
67
66
OVDD
+
ANALOG
INPUT B
INPUT
S/H
–
12-BIT
PIPELINED
ADC CORE
OUTPUT
DRIVERS
D11B
•
••
65
0
50
100 150 200 250 300 350
INPUT FREQUENCY (MHz) 2282 TA01b
D0B
OGND
2282 TA01
2282fb
1
LTC2282
ABSOLUTE MAXIMUM RATINGS
PIN CONFIGURATION
OVDD = VDD (Notes 1, 2)
64 GND
63 VDD
62 SENSEA
61 VCMA
60 MODE
59 SHDNA
58 OEA
57 OFA
56 DA11
55 DA10
54 DA9
53 DA8
52 DA7
51 DA6
50 OGND
49 OVDD
TOP VIEW
Supply Voltage (VDD) ..................................................4V
Digital Output Ground Voltage (OGND) ........ –0.3V to 1V
Analog Input Voltage (Note 3) .......–0.3V to (VDD + 0.3V)
Digital Input Voltage......................–0.3V to (VDD + 0.3V)
Digital Output Voltage ................ –0.3V to (OVDD + 0.3V)
Power Dissipation .............................................1500mW
Operating Temperature Range
LTC2282C ................................................ 0°C to 70°C
LTC2282I..............................................–40°C to 85°C
Storage Temperature Range...................–65°C to 125°C
AINA+ 1
AINA– 2
REFHA 3
REFHA 4
REFLA 5
REFLA 6
VDD 7
CLKA 8
CLKB 9
VDD 10
REFLB 11
REFLB 12
REFHB 13
REFHB 14
AINB– 15
AINB+ 16
48 DA5
47 DA4
46 DA3
45 DA2
44 DA1
43 DA0
42 NC
41 NC
40 OFB
39 DB11
38 DB10
37 DB9
36 DB8
35 DB7
34 DB6
33 DB5
GND 17
VDD 18
SENSEB 19
VCMB 20
MUX 21
SHDNB 22
OEB 23
NC 24
NC 25
DB0 26
DB1 27
DB2 28
DB3 29
DB4 30
OGND 31
OVDD 32
65
UP PACKAGE
64-LEAD (9mm s 9mm) PLASTIC QFN
TJMAX = 125°C, QJA = 20°C/W
EXPOSED PAD (PIN 65) IS GND AND MUST BE SOLDERED TO PCB
ORDER INFORMATION
LEAD FREE FINISH
TAPE AND REEL
PART MARKING*
PACKAGE DESCRIPTION
TEMPERATURE RANGE
LTC2282IUP#PBF
LTC2282IUP#TRPBF
LTC2282UP
64-Lead (9mm × 9mm) Plastic QFN
–40°C to 85°C
LTC2282CUP#PBF
LTC2282CUP#TRPBF
LTC2282UP
64-Lead (9mm × 9mm) Plastic QFN
0°C to 70°C
LEAD BASED FINISH
TAPE AND REEL
PART MARKING*
PACKAGE DESCRIPTION
TEMPERATURE RANGE
LTC2282IUP
LTC2282IUP#TR
LTC2282UP
64-Lead (9mm × 9mm) Plastic QFN
–40°C to 85°C
LTC2282CUP
LTC2282CUP#TR
LTC2282UP
64-Lead (9mm × 9mm) Plastic QFN
0°C to 70°C
Consult LTC Marketing for parts specified with wider operating temperature ranges. *Temperature grades are identified by a label on the shipping container.
For more information on lead free part marking, go to: http://www.linear.com/leadfree/
For more information on tape and reel specifications, go to: http://www.linear.com/tapeandreel/
CONVERTER CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. (Note 4)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
l
12
Integral Linearity Error
Differential Analog Input (Note 5)
l
–1.5
±0.4
1.5
LSB
Differential Linearity Error
Differential Analog Input
l
–0.9
±0.2
0.9
LSB
Offset Error
(Note 6)
l
–12
±2
12
mV
Gain Error
External Reference
l
–2.5
±0.5
2.5
%FS
Resolution (No Missing Codes)
Offset Drift
Bits
±10
μV/°C
2282fb
2
LTC2282
CONVERTER CHARACTERISTICS
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. (Note 4)
PARAMETER
CONDITIONS
Full-Scale Drift
Internal Reference
Gain Matching
MIN
TYP
UNITS
±30
ppm/°C
External Reference
±5
ppm/°C
External Reference
±0.3
%FS
±2
mV
0.3
LSBRMS
Offset Matching
Transition Noise
MAX
SENSE = 1V
ANALOG INPUT
The l denotes the specifications which apply over the full operating temperature range, otherwise
specifications are at TA = 25°C. (Note 4)
SYMBOL
PARAMETER
CONDITIONS
VIN
Analog Input Range (AIN+ – AIN–)
MIN
2.85V < VDD < 3.4V (Note 7)
l
VIN,CM
Analog Input Common Mode (AIN+ + AIN–)/2
Differential Input Drive (Note 7)
Single Ended Input Drive (Note 7)
l
l
1
0.5
IIN
Analog Input Leakage Current
0V < AIN+, AIN– < VDD
l
ISENSE
SENSEA, SENSEB Input Leakage
0V < SENSEA, SENSEB < 1V
l
IMODE
MODE Input Leakage Current
0V < MODE < VDD
l
TYP
MAX
UNITS
±0.5V to ±1V
1.5
1.5
V
1.9
2
V
V
–1
1
μA
–3
3
μA
–3
3
μA
tAP
Sample-and-Hold Acquisition Delay Time
tJITTER
Sample-and-Hold Acquisition Delay Time Jitter
0.2
psRMS
CMRR
Analog Input Common Mode Rejection Ratio
80
dB
575
MHz
Full Power Bandwidth
0
Figure 8 Test Circuit
ns
DYNAMIC ACCURACY
The l denotes the specifications which apply over the full operating temperature range,
otherwise specifications are at TA = 25°C. AIN = –1dBFS. (Note 4)
SYMBOL
PARAMETER
SNR
Signal-to-Noise Ratio
CONDITIONS
MIN
70.1
dB
70.1
dB
70
dB
l
68.5
5MHz Input
30MHz Input
Spurious Free Dynamic Range
4th Harmonic or Higher
Signal-to-Noise Plus Distortion Ratio
86
dB
dB
dB
5MHz Input
90
dB
30MHz Input
90
dB
90
dB
140MHz Input
90
dB
5MHz Input
70
dB
79
30MHz Input
70MHz Input
140MHz Input
IMD
dB
79
l
72
dB
88
84
70MHz Input
S/(N+D)
l
69.7
140MHz Input
70MHz Input
SFDR
UNITS
5MHz Input
140MHz Input
Spurious Free Dynamic Range
2nd or 3rd Harmonic
MAX
30MHz Input
70MHz Input
SFDR
TYP
Intermodulation Distortion
fIN = 40MHz, 41MHz
Crosstalk
fIN = 100MHz
l
67.5
70
dB
69.9
dB
68.7
dB
85
dB
–110
dB
2282fb
3
LTC2282
INTERNAL REFERENCE CHARACTERISTICS
(Note 4)
PARAMETER
CONDITIONS
MIN
TYP
MAX
VCM Output Voltage
IOUT = 0
1.475
1.500
1.525
VCM Output Tempco
±25
UNITS
V
ppm/°C
VCM Line Regulation
2.85V < VDD < 3.4V
3
mV/ V
VCM Output Resistance
–1mA < IOUT < 1mA
4
Ω
DIGITAL INPUTS AND DIGITAL OUTPUTS
The l denotes the specifications which apply over the
full operating temperature range, otherwise specifications are at TA = 25°C. (Note 4)
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
LOGIC INPUTS (CLK, OE, SHDN, MUX)
VIH
High Level Input Voltage
VDD = 3V
l
VIL
Low Level Input Voltage
VDD = 3V
l
IIN
Input Current
VIN = 0V to VDD
l
CIN
Input Capacitance
(Note 7)
COZ
Hi-Z Output Capacitance
OE = High (Note 7)
3
pF
ISOURCE
Output Source Current
VOUT = 0V
50
mA
ISINK
Output Sink Current
VOUT = 3V
50
mA
VOH
High Level Output Voltage
IO = –10μA
IO = –200μA
l
IO = 10μA
IO = 1.6mA
l
2
V
–10
0.8
V
10
μA
3
pF
LOGIC OUTPUTS
OVDD = 3V
VOL
Low Level Output Voltage
2.7
2.995
2.99
0.0005
0.09
V
V
0.4
V
V
OVDD = 2.5V
VOH
High Level Output Voltage
IO = –200μA
2.49
V
VOL
Low Level Output Voltage
IO = 1.6mA
0.09
V
VOH
High Level Output Voltage
IO = –200μA
1.79
V
VOL
Low Level Output Voltage
IO = 1.6mA
0.09
V
OVDD = 1.8V
2282fb
4
LTC2282
POWER REQUIREMENTS
The ● denotes the specifications which apply over the full operating temperature
range, otherwise specifications are at TA = 25°C. (Note 8)
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
VDD
Analog Supply Voltage
(Note 9)
l
2.85
3
3.4
OVDD
Output Supply Voltage
IVDD
Supply Current
(Note 9)
l
0.5
3
3.6
V
Both ADCs at fS(MAX)
l
180
210
mA
PDISS
Power Dissipation
Both ADCs at fS(MAX)
l
540
630
mW
PSHDN
Shutdown Power (Each Channel)
SHDN = H, OE = H, No CLK
2
mW
PNAP
Nap Mode Power (Each Channel)
SHDN = H, OE = L, No CLK
15
mW
V
TIMING CHARACTERISTICS
The l denotes the specifications which apply over the full operating temperature
range, otherwise specifications are at TA = 25°C. (Note 4)
SYMBOL
PARAMETER
CONDITIONS
fs
Sampling Frequency
(Note 9)
l
MIN
1
TYP
MAX
UNITS
105
MHz
tL
CLK Low Time
Duty Cycle Stabilizer Off (Note 7)
Duty Cycle Stabilizer On (Note 7)
l
l
4.5
3
4.76
4.76
500
500
ns
ns
tH
CLK High Time
Duty Cycle Stabilizer Off (Note 7)
Duty Cycle Stabilizer On (Note 7)
l
l
4.5
3
4.76
4.76
500
500
ns
ns
tAP
Sample-and-Hold Aperture Delay
tD
CLK to DATA Delay
CL = 5pF (Note 7)
l
1.4
2.7
5.4
ns
tMD
MUX to DATA Delay
CL = 5pF (Note 7)
l
1.4
2.7
5.4
ns
Data Access Time After OE↓
CL = 5pF (Note 7)
l
4.3
10
ns
BUS Relinquish Time
(Note 7)
l
3.3
8.5
0
Pipeline Latency
Note 1: Stresses beyond those listed under Absolute Maximum Ratings
may cause permanent damage to the device. Exposure to any Absolute
Maximum Rating condition for extended periods may affect device
reliability and lifetime.
Note 2: All voltage values are with respect to ground with GND and OGND
wired together (unless otherwise noted).
Note 3: When these pin voltages are taken below GND or above VDD, they
will be clamped by internal diodes. This product can handle input currents
of greater than 100mA below GND or above VDD without latchup.
Note 4: VDD = 3V, fSAMPLE = 105MHz, input range = 2VP-P with differential
drive, unless otherwise noted.
5
ns
ns
Cycles
Note 5: Integral nonlinearity is defined as the deviation of a code from a
straight line passing through the actual endpoints of the transfer curve.
The deviation is measured from the center of the quantization band.
Note 6: Offset error is the offset voltage measured from –0.5 LSB when
the output code flickers between 0000 0000 0000 and 1111 1111 1111.
Note 7: Guaranteed by design, not subject to test.
Note 8: VDD = 3V, fSAMPLE = 105MHz, input range = 1VP-P with differential
drive. The supply current and power dissipation are the sum total for both
channels with both channels active.
Note 9: Recommended operating conditions.
2282fb
5
LTC2282
TYPICAL PERFORMANCE CHARACTERISTICS
Crosstalk vs Input Frequency
Typical INL, 2V Range, 105Msps
INL ERROR (LSB)
–110
–115
–120
–125
1.0
0.8
0.8
0.6
0.6
0.4
0.4
0.2
0
–0.2
–0.4
0
–0.2
–0.4
–0.6
–0.6
–0.8
–0.8
20
40
60
80
INPUT FREQUENCY (MHz)
100
–1.0
0
1024
2282 G01
8192 Point FFT, fIN = 5MHz,
–1dB, 2V Range, 105Msps
2048
CODE
3072
4096
0
0
–10
–10
–20
–20
–20
–30
–30
–30
–60
–70
–80
AMPLITUDE (dB)
0
–50
–40
–50
–60
–70
–80
–60
–70
–80
–90
–100
–100
–100
–110
–110
–110
–120
–120
30
40
20
FREQUENCY (MHz)
50
0
–10
–20
–20
–30
–30
AMPLITUDE (dB)
0
–40
–50
–60
–70
–80
30
40
20
FREQUENCY (MHz)
50
2282 G21
60000
56911
50000
40000
30000
–70
20000
–80
–90
–110
–110
2282 G22
10
Grounded Input Histogram,
105Msps
–60
–100
50
0
2282 G20
–50
–90
30
40
20
FREQUENCY (MHz)
–120
50
–40
–100
10
30
40
20
FREQUENCY (MHz)
8192 Point 2-Tone FFT,
fIN = 28.2MHz and 26.8MHz,
–1dB, 2V Range, 105Msps
–10
0
10
2282 G19
8192 Point FFT, fIN = 140MHz,
–1dB, 2V Range, 105Msps
–120
0
4096
2282 G18
–50
–90
10
3072
–40
–90
0
2048
CODE
8192 Point FFT, fIN = 70MHz,
–1dB, 2V Range, 105Msps
–10
–40
1024
0
2282 G17
8192 Point FFT, fIN = 30MHz,
–1dB, 2V Range, 105Msps
AMPLITUDE (dB)
AMPLITUDE (dB)
0
–1.0
–130
AMPLITUDE (dB)
0.2
COUNT
CROSSTALK (dB)
–105
Typical DNL, 2V Range, 105Msps
1.0
DNL ERROR (LSB)
–100
–120
10000
0
0
10
30
40
20
FREQUENCY (MHz)
50
2282 G23
6704
0
2044
1913
2045
0
2046
CODE
2047
2048
2282 G24
2282fb
6
LTC2282
TYPICAL PERFORMANCE CHARACTERISTICS
SNR vs Input Frequency,
–1dB, 2V Range, 105Msps
SNR and SFDR vs Sample Rate,
2V Range, fIN = 5MHz, –1dB
SFDR vs Input Frequency, –1dB,
2V Range, 105Msps
73
95
90
SFDR
72
90
69
68
SNR AND SFDR (dBFS)
70
SFDR (dBFS)
SNR (dBFS)
71
85
80
75
67
SNR
70
60
70
66
65
50
65
150 200 250 300 350
2282 G25
INPUT FREQUENCY (MHz)
100
0
SNR vs Input Level, fIN = 70MHz,
2V Range, 105Msps
50
50
100 150 200 250 300 350
2282 G26
INPUT FREQUENCY (MHz)
0
SFDR vs Input Level, fIN = 70MHz,
2V Range, 105Msps
100
70
dBFS
SFDR (dBc AND dBFS)
50
dBc
40
30
20
80
170
70
dBc
60
50
40
–50
–40
–20
–30
INPUT LEVEL (dBFS)
–10
0
30
0
–60
2282 G28
2V RANGE
160
150
1V RANGE
140
130
120
10
110
–50
–40
–30
–20
INPUT LEVEL (dBFS)
–10
0
0
20
2282 G29
IOVDD vs Sample Rate, 5MHz Sine
Wave Input, –1dB, OVDD = 1.8V
80
40
60
SAMPLE RATE (Msps)
100
120
22532 G30
SNR vs SENSE, fIN = 5MHz, –1dB
17.5
72
15.0
71
70
SNR (dBFS)
12.5
IOVDD (mA)
0
–60
140
2282 G27
180
20
10
120
190
dBFS
90
60
40
60
80 100
SAMPLE RATE (Msps)
200
110
80
20
IVDD vs Sample Rate, 5MHz Sine
Wave Input, –1dB
IVDD (mA)
0
SNR (dBc AND dBFS)
80
10.0
7.5
5.0
69
68
67
66
2.5
65
0
0
20
80
120
60
100
40
2282 G31
SAMPLE RATE (Msps)
64
0.4
0.5
0.6
0.7 0.8 0.9
SENSE PIN (V)
1.0
1.1
2282 G33
2282fb
7
LTC2282
PIN FUNCTIONS
AINA+ (Pin 1): Channel A Positive Differential Analog
Input.
AINA– (Pin 2): Channel A Negative Differential Analog
Input.
REFHA (Pins 3, 4): Channel A High Reference. Short
together and bypass to Pins 5, 6 with a 0.1μF ceramic chip
capacitor as close to the pin as possible. Also bypass to
Pins 5, 6 with an additional 2.2μF ceramic chip capacitor
and to ground with a 1μF ceramic chip capacitor.
REFLA (Pins 5, 6): Channel A Low Reference. Short
together and bypass to Pins 3, 4 with a 0.1μF ceramic chip
capacitor as close to the pin as possible. Also bypass to
Pins 3, 4 with an additional 2.2μF ceramic chip capacitor
and to ground with a 1μF ceramic chip capacitor.
VDD (Pins 7, 10, 18, 63): Analog 3V Supply. Bypass to
GND with 0.1μF ceramic chip capacitors.
CLKA (Pin 8): Channel A Clock Input. The input sample
starts on the positive edge.
CLKB (Pin 9): Channel B Clock Input. The input sample
starts on the positive edge.
REFLB (Pins 11, 12): Channel B Low Reference. Short
together and bypass to Pins 13, 14 with a 0.1μF ceramic
chip capacitor as close to the pin as possible. Also bypass
to Pins 13, 14 with an additional 2.2μF ceramic chip capacitor and to ground with a 1μF ceramic chip capacitor.
REFHB (Pins 13, 14): Channel B High Reference. Short
together and bypass to Pins 11, 12 with a 0.1μF ceramic
chip capacitor as close to the pin as possible. Also bypass
to Pins 11, 12 with an additional 2.2μF ceramic chip capacitor and to ground with a 1μF ceramic chip capacitor.
AINB– (Pin 15): Channel B Negative Differential Analog
Input.
AINB+ (Pin 16): Channel B Positive Differential Analog
Input.
GND (Pins 17, 64): ADC Power Ground.
SENSEB (Pin 19): Channel B Reference Programming Pin.
Connecting SENSEB to VCMB selects the internal reference
and a ±0.5V input range. VDD selects the internal reference
and a ±1V input range. An external reference greater than
0.5V and less than 1V applied to SENSEB selects an input
range of ±VSENSEB. ±1V is the largest valid input range.
VCMB (Pin 20): Channel B 1.5V Output and Input Common
Mode Bias. Bypass to ground with 2.2μF ceramic chip
capacitor. Do not connect to VCMA.
MUX (Pin 21): Digital Output Multiplexer Control. If MUX is
high, channel A comes out on DA0-DA11, OFA; channel B
comes out on DB0-DB11, OFB. If MUX is low, the output
busses are swapped and channel A comes out on DB0DB11, OFB; channel B comes out on DA0-DA11, OFA. To
multiplex both channels onto a single output bus, connect
MUX, CLKA and CLKB together. (This is not recommended
at clock frequencies above 80Msps.)
SHDNB (Pin 22): Channel B Shutdown Mode Selection
Pin. Connecting SHDNB to GND and OEB to GND results
in normal operation with the outputs enabled. Connecting
SHDNB to GND and OEB to VDD results in normal operation
with the outputs at high impedance. Connecting SHDNB
to VDD and OEB to GND results in nap mode with the
outputs at high impedance. Connecting SHDNB to VDD
and OEB to VDD results in sleep mode with the outputs
at high impedance.
OEB (Pin 23): Channel B Output Enable Pin. Refer to
SHDNB pin function.
NC (Pins 24, 25, 41, 42): Do Not Connect These Pins.
DB0 – DB11 (Pins 26 to 30, 33 to 39): Channel B Digital
Outputs. DB11 is the MSB.
OGND (Pins 31, 50): Output Driver Ground.
OVDD (Pins 32, 49): Positive Supply for the Output Drivers.
Bypass to ground with a 0.1μF ceramic chip capacitor.
OFB (Pin 40): Channel B Overflow/Underflow Output. High
when an overflow or underflow has occurred.
DA0 – DA11 (Pins 43 to 48, 51 to 56): Channel A Digital
Outputs. DA11 is the MSB.
OFA (Pin 57): Channel A Overflow/Underflow Output. High
when an overflow or underflow has occurred.
OEA (Pin 58): Channel A Output Enable Pin. Refer to
SHDNA pin function.
2282fb
8
LTC2282
PIN FUNCTIONS
SHDNA (Pin 59): Channel A Shutdown Mode Selection
Pin. Connecting SHDNA to GND and OEA to GND results
in normal operation with the outputs enabled. Connecting
SHDNA to GND and OEA to VDD results in normal operation
with the outputs at high impedance. Connecting SHDNA
to VDD and OEA to GND results in nap mode with the
outputs at high impedance. Connecting SHDNA to VDD
and OEA to VDD results in sleep mode with the outputs
at high impedance.
MODE (Pin 60): Output Format and Clock Duty Cycle
Stabilizer Selection Pin. Note that MODE controls both
channels. Connecting MODE to GND selects offset binary
output format and turns the clock duty cycle stabilizer
off. 1/3 VDD selects offset binary output format and turns
the clock duty cycle stabilizer on. 2/3 VDD selects 2’s
complement output format and turns the clock duty cycle
stabilizer on. VDD selects 2’s complement output format
and turns the clock duty cycle stabilizer off.
VCMA (Pin 61): Channel A 1.5V Output and Input Common
Mode Bias. Bypass to ground with a 2.2μF ceramic chip
capacitor. Do not connect to VCMB.
SENSEA (Pin 62): Channel A Reference Programming Pin.
Connecting SENSEA to VCMA selects the internal reference
and a ±0.5V input range. VDD selects the internal reference
and a ±1V input range. An external reference greater than
0.5V and less than 1V applied to SENSEA selects an input
range of ±VSENSEA. ±1V is the largest valid input range.
Exposed Pad (Pin 65): ADC Power Ground. The Exposed
Pad on the bottom of the package needs to be soldered
to ground.
FUNCTIONAL BLOCK DIAGRAM
AIN+
AIN–
VCM
INPUT
S/H
FIRST PIPELINED
ADC STAGE
SECOND PIPELINED
ADC STAGE
THIRD PIPELINED
ADC STAGE
FOURTH PIPELINED
ADC STAGE
FIFTH PIPELINED
ADC STAGE
1.5V
REFERENCE
SIXTH PIPELINED
ADC STAGE
SHIFT REGISTER
AND CORRECTION
2.2μF
RANGE
SELECT
REFH
SENSE
REFL
INTERNAL CLOCK SIGNALS
OVDD
REF
BUF
OF
D11
CLOCK/DUTY
CYCLE
CONTROL
DIFF
REF
AMP
CONTROL
LOGIC
OUTPUT
DRIVERS
•
•
•
D0
REFH
0.1μF
2282 F01
REFL
OGND
CLK
MODE
SHDN
OE
2.2μF
1μF
1μF
Figure 1. Functional Block Diagram (Only One Channel is Shown)
2282fb
9
LTC2282
TIMING DIAGRAMS
Dual Digital Output Bus Timing
(Only One Channel is Shown)
tAP
ANALOG
INPUT
N+4
N+2
N
N+1
tH
N+3
N+5
tL
CLK
tD
N–4
N–5
D0-D11, OF
N–3
N–2
N–1
N
2282 TD01
Multiplexed Digital Output Bus Timing
tAPA
ANALOG
INPUT A
A+4
A+2
A
A+1
A+3
tAPB
ANALOG
INPUT B
B+4
B+2
B
B+1
tH
tL
A–5
B–5
B+3
CLKA = CLKB = MUX
D0A-D11A, OFA
A–4
tD
D0B-D11B, OFB
B–5
B–4
A–3
B–3
A–2
B–2
B–3
A–3
B–2
A–2
A–1
tMD
A–5
B–4
A–4
B–1
2282 TD02
2282fb
10
LTC2282
APPLICATIONS INFORMATION
DYNAMIC PERFORMANCE
Signal-to-Noise Plus Distortion Ratio
The signal-to-noise plus distortion ratio [S/(N + D)] is
the ratio between the RMS amplitude of the fundamental input frequency and the RMS amplitude of all other
frequency components at the ADC output. The output is
band limited to frequencies above DC to below half the
sampling frequency.
Signal-to-Noise Ratio
The signal-to-noise ratio (SNR) is the ratio between the
RMS amplitude of the fundamental input frequency and
the RMS amplitude of all other frequency components
except the first five harmonics and DC.
2fa + fb, 2fb + fa, 2fa – fb and 2fb – fa. The intermodulation distortion is defined as the ratio of the RMS value of
either input tone to the RMS value of the largest 3rd order
intermodulation product.
Spurious Free Dynamic Range (SFDR)
Spurious free dynamic range is the peak harmonic or
spurious noise that is the largest spectral component
excluding the input signal and DC. This value is expressed
in decibels relative to the RMS value of a full scale input
signal.
Input Bandwidth
The input bandwidth is that input frequency at which the
amplitude of the reconstructed fundamental is reduced
by 3dB for a full scale input signal.
Total Harmonic Distortion
Total harmonic distortion is the ratio of the RMS sum
of all harmonics of the input signal to the fundamental
itself. The out-of-band harmonics alias into the frequency
band between DC and half the sampling frequency. THD
is expressed as:
THD = 20Log (√(V22 + V32 + V42 + . . . Vn2)/V1)
where V1 is the RMS amplitude of the fundamental frequency and V2 through Vn are the amplitudes of the second
through nth harmonics. The THD calculated in this data
sheet uses all the harmonics up to the fifth.
Aperture Delay Time
The time from when CLK reaches midsupply to the instant that
the input signal is held by the sample and hold circuit.
Aperture Delay Jitter
The variation in the aperture delay time from conversion
to conversion. This random variation will result in noise
when sampling an AC input. The signal to noise ratio due
to the jitter alone will be:
SNRJITTER = –20log (2π • fIN • tJITTER)
Intermodulation Distortion
Crosstalk
If the ADC input signal consists of more than one spectral
component, the ADC transfer function nonlinearity can
produce intermodulation distortion (IMD) in addition to
THD. IMD is the change in one sinusoidal input caused
by the presence of another sinusoidal input at a different
frequency.
Crosstalk is the coupling from one channel (being driven
by a full-scale signal) onto the other channel (being driven
by a –1dBFS signal).
If two pure sine waves of frequencies fa and fb are applied to the ADC input, nonlinearities in the ADC transfer
function can create distortion products at the sum and
difference frequencies of mfa ± nfb, where m and n = 0,
1, 2, 3, etc. The 3rd order intermodulation products are
CONVERTER OPERATION
As shown in Figure 1, the LTC2282 is a dual CMOS pipelined
multistep converter. The converter has six pipelined ADC
stages; a sampled analog input will result in a digitized
value five cycles later (see the Timing Diagram section).
For optimal AC performance the analog inputs should be
driven differentially. For cost sensitive applications, the
2282fb
11
LTC2282
APPLICATIONS INFORMATION
analog inputs can be driven single-ended with slightly
worse harmonic distortion. The CLK input is single-ended.
The LTC2282 has two phases of operation, determined by
the state of the CLK input pin.
Each pipelined stage shown in Figure 1 contains an ADC,
a reconstruction DAC and an interstage residue amplifier.
In operation, the ADC quantizes the input to the stage and
the quantized value is subtracted from the input by the
DAC to produce a residue. The residue is amplified and
output by the residue amplifier. Successive stages operate
out of phase so that when the odd stages are outputting
their residue, the even stages are acquiring that residue
and vice versa.
When CLK is low, the analog input is sampled differentially
directly onto the input sample-and-hold capacitors, inside
the “Input S/H” shown in the Functional Block Diagram.
At the instant that CLK transitions from low to high, the
sampled input is held. While CLK is high, the held input
voltage is buffered by the S/H amplifier which drives the
first pipelined ADC stage. The first stage acquires the
output of the S/H during this high phase of CLK. When
CLK goes back low, the first stage produces its residue
which is acquired by the second stage. At the same
time, the input S/H goes back to acquiring the analog
input. When CLK goes back high, the second stage produces its residue which is acquired by the third stage.
An identical process is repeated for the third, fourth and
fifth stages, resulting in a fifth stage residue that is sent
to the sixth stage ADC for final evaluation.
Each ADC stage following the first has additional range to
accommodate flash and amplifier offset errors. Results
from all of the ADC stages are digitally synchronized such
that the results can be properly combined in the correction
logic before being sent to the output buffer.
SAMPLE/HOLD OPERATION AND INPUT DRIVE
Sample/Hold Operation
Figure 2 shows an equivalent circuit for the LTC2282 CMOS
differential sample-and-hold. The analog inputs are connected to the sampling capacitors (CSAMPLE) through NMOS
transistors. The capacitors shown attached to each input
(CPARASITIC) are the summation of all other capacitance
associated with each input.
During the sample phase when CLK is low, the transistors
connect the analog inputs to the sampling capacitors and
they charge to and track the differential input voltage. When
CLK transitions from low to high, the sampled input voltage
is held on the sampling capacitors. During the hold phase
when CLK is high, the sampling capacitors are disconnected
from the input and the held voltage is passed to the ADC
core for processing. As CLK transitions from high to low,
the inputs are reconnected to the sampling capacitors to
LTC2282
VDD
AIN+
CSAMPLE
4pF
15Ω
CPARASITIC
1pF
VDD
AIN–
CSAMPLE
4pF
15Ω
CPARASITIC
1pF
VDD
CLK
2282 F02
Figure 2. Equivalent Input Circuit
2282fb
12
LTC2282
APPLICATIONS INFORMATION
acquire a new sample. Since the sampling capacitors still
hold the previous sample, a charging glitch proportional to
the change in voltage between samples will be seen at this
time. If the change between the last sample and the new
sample is small, the charging glitch seen at the input will
be small. If the input change is large, such as the change
seen with input frequencies near Nyquist, then a larger
charging glitch will be seen.
Single-Ended Input
For cost sensitive applications, the analog inputs can be
driven single-ended. With a single-ended input the harmonic distortion and INL will degrade, but the SNR and
DNL will remain unchanged. For a single-ended input, AIN+
should be driven with the input signal and AIN– should be
connected to 1.5V or VCM.
Common Mode Bias
For optimal performance, the analog inputs should be
driven differentially. Each input should swing ±0.5V for the
2V range or ±0.25V for the 1V range, around a common
mode voltage of 1.5V. The VCM output pin may be used
to provide the common mode bias level. VCM can be tied
directly to the center tap of a transformer to set the DC
input level or as a reference level to an op amp differential
driver circuit. The VCM pin must be bypassed to ground
close to the ADC with a 2.2μF, or greater, capacitor.
Input Drive Impedance
As with all high performance, high speed ADCs, the dynamic performance of the LTC2282 can be influenced by
the input drive circuitry, particularly the second and third
harmonics. Source impedance and reactance can influence
SFDR. At the falling edge of CLK, the sample-and-hold
circuit will connect the 4pF sampling capacitor to the input
pin and start the sampling period. The sampling period
ends when CLK rises, holding the sampled input on the
sampling capacitor. Ideally the input circuitry should be fast
enough to fully charge the sampling capacitor during the
sampling period 1/(2FENCODE); however, this is not always
possible and the incomplete settling may degrade the SFDR.
The sampling glitch has been designed to be as linear as
possible to minimize the effects of incomplete settling.
For the best performance, it is recommended to have a
source impedance of 100Ω, or less, for each input. The
source impedance should be matched for the differential
inputs. Poor matching will result in higher even order
harmonics, especially the second.
Input Drive Circuits
Figure 3 shows the LTC2282 being driven by an RF transformer with a center tapped secondary. The secondary
center tap is DC biased with VCM, setting the ADC input
signal at its optimum DC level. Terminating on the transformer secondary is desirable, as this provides a common
mode path for charging glitches caused by the sample and
hold. Figure 3 shows a 1:1 turns ratio transformer. Other
turns ratios can be used if the source impedance seen
by the ADC does not exceed 100Ω for each ADC input.
A disadvantage of using a transformer is the loss of low
frequency response. Most small RF transformers have
poor performance at frequencies below 1MHz.
VCM
2.2μF
0.1μF
ANALOG
INPUT
T1
1:1
25Ω
25Ω
AIN+
LTC2282
0.1μF
12pF
25Ω
T1 = MA/COM ETC1-1T 25Ω
RESISTORS, CAPACITORS
ARE 0402 PACKAGE SIZE
AIN–
2282 F03
Figure 3. Single-Ended to Differential Conversion
Using a Transformer
Figure 4 demonstrates the use of a differential amplifier to
convert a single-ended input signal into a differential input
signal. The advantage of this method is that it provides
low frequency input response; however, the limited gain
bandwidth of most op amps will limit the SFDR at high
input frequencies.
2282fb
13
LTC2282
APPLICATIONS INFORMATION
VCM
VCM
HIGH SPEED
DIFFERENTIAL
25Ω
AMPLIFIER
ANALOG
INPUT
+
AIN+
0.1μF
LTC2282
12Ω
ANALOG
INPUT
25Ω
+
CM
–
2.2μF
2.2μF
25Ω
0.1μF
AIN–
LTC2282
0.1μF
T1
12pF
–
AIN+
8pF
25Ω
12Ω
AIN–
T1 = MA/COM, ETC 1-1-13
RESISTORS, CAPACITORS
ARE 0402 PACKAGE SIZE
2282 F04
2282 F06
Figure 4. Differential Drive with an Amplifier
Figure 5 shows a single-ended input circuit. The impedance
seen by the analog inputs should be matched. This circuit
is not recommended if low distortion is required.
Figure 6. Recommended Front End Circuit for
Input Frequencies Between 70MHz and 170MHz
VCM
2.2μF
VCM
1k
0.1μF
ANALOG
INPUT
1k
25Ω
0.1μF
AIN+
ANALOG
INPUT
2.2μF
25Ω
AIN+
T1
LTC2282
0.1μF
12pF
25Ω
25Ω
T1 = MA/COM, ETC 1-1-13
RESISTORS, CAPACITORS
ARE 0402 PACKAGE SIZE
AIN–
0.1μF
LTC2282
0.1μF
AIN–
2282 F07
2282 F05
Figure 7. Recommended Front End Circuit for
Input Frequencies Between 170MHz and 300MHz
Figure 5. Single-Ended Drive
The 25Ω resistors and 12pF capacitor on the analog
inputs serve two purposes: isolating the drive circuitry
from the sample-and-hold charging glitches and limiting
the wideband noise at the converter input.
For input frequencies above 70MHz, the input circuits of
Figure 6, 7 and 8 are recommended. The balun transformer
gives better high frequency response than a flux coupled
center tapped transformer. The coupling capacitors allow
the analog inputs to be DC biased at 1.5V. In Figure 8, the
series inductors are impedance matching elements that
maximize the ADC bandwidth.
VCM
2.2μF
0.1μF
6.8nH
ANALOG
INPUT
25Ω
AIN+
LTC2282
0.1μF
T1
0.1μF
25Ω
6.8nH
–
AIN
T1 = MA/COM, ETC 1-1-13
RESISTORS, CAPACITORS, INDUCTORS
ARE 0402 PACKAGE SIZE
2282 F08
Figure 8. Recommended Front End Circuit for
Input Frequencies Above 300MHz
2282fb
14
LTC2282
APPLICATIONS INFORMATION
Reference Operation
Figure 9 shows the LTC2282 reference circuitry consisting
of a 1.5V bandgap reference, a difference amplifier and
switching and control circuit. The internal voltage reference
can be configured for two pin selectable input ranges of
2V (±1V differential) or 1V (±0.5V differential). Tying the
SENSE pin to VDD selects the 2V range; tying the SENSE
pin to VCM selects the 1V range.
The 1.5V bandgap reference serves two functions: its
output provides a DC bias point for setting the common
mode voltage of any external input circuitry; additionally,
the reference is used with a difference amplifier to generate the differential reference levels needed by the internal
ADC circuitry. An external bypass capacitor is required
for the 1.5V reference output, VCM. This provides a high
frequency low impedance path to ground for internal and
external circuitry.
LTC2282
1.5V
VCM
4Ω
The difference amplifier generates the high and low
reference for the ADC. High speed switching circuits are
connected to these outputs and they must be externally
bypassed. Each output has two pins. The multiple output
pins are needed to reduce package inductance. Bypass
capacitors must be connected as shown in Figure 9. Each
ADC channel has an independent reference with its own
bypass capacitors. The two channels can be used with
the same or different input ranges.
Other voltage ranges between the pin selectable ranges
can be programmed with two external resistors, as shown
in Figure 10. An external reference can be used by applying its output directly or through a resistor divider to
SENSE. It is not recommended to drive the SENSE pin
with a logic device. The SENSE pin should be tied to the
appropriate level as close to the converter as possible. If
the SENSE pin is driven externally, it should be bypassed
to ground as close to the device as possible with a 1μF
ceramic capacitor. For the best channel matching, connect
an external reference to SENSEA and SENSEB.
1.5V BANDGAP
REFERENCE
2.2μF
1.5V
1V
VCM
0.5V
2.2μF
12k
TIE TO VDD FOR 2V RANGE;
TIE TO VCM FOR 1V RANGE;
RANGE = 2 • VSENSE FOR
0.5V < VSENSE < 1V
RANGE
DETECT
AND
CONTROL
0.75V
12k
LTC2282
SENSE
1μF
SENSE
2282 F10
BUFFER
INTERNAL ADC
HIGH REFERENCE
1μF
Figure 10. 1.5V Range ADC
REFH
Input Range
2.2μF
0.1μF
The input range can be set based on the application.
The 2V input range will provide the best signal-to-noise
performance while maintaining excellent SFDR. The 1V
input range will have better SFDR performance, but the
SNR will degrade by 4dB. See the Typical Performance
Characteristics section.
DIFF AMP
1μF
REFL
INTERNAL ADC
LOW REFERENCE
2282 F09
Driving the Clock Input
Figure 9. Equivalent Reference Circuit
The CLK inputs can be driven directly with a CMOS or TTL
level signal. A sinusoidal clock can also be used along with a
low jitter squaring circuit before the CLK pin (Figure 11).
2282fb
15
LTC2282
APPLICATIONS INFORMATION
CLEAN
SUPPLY
4.7μF
SINUSOIDAL
CLOCK
INPUT
FERRITE
BEAD
FERRITE
BEAD
0.1μF
0.1μF
1k
0.1μF
CLK
50Ω
1k
CLEAN
SUPPLY
4.7μF
CLK
LTC2282
100Ω
LTC2282
NC7SVU04
IF LVDS, USE FIN1002 OR FIN1018.
FOR PECL, USE AZ1000ELT21 OR SIMILAR
2282 F12
2282 F11
Figure 11. Sinusoidal Single-Ended CLK Drive
Figure 12. CLK Drive Using an LVDS or PECL to CMOS Converter
The noise performance of the LTC2282 can depend on the
clock signal quality as much as on the analog input. Any
noise present on the clock signal will result in additional
aperture jitter that will be RMS summed with the inherent
ADC aperture jitter.
In applications where jitter is critical, such as when digitizing high input frequencies, use as large an amplitude
as possible. Also, if the ADC is clocked with a sinusoidal
signal, filter the CLK signal to reduce wideband noise and
distortion products generated by the source.
It is recommended that CLKA and CLKB are shorted together and driven by the same clock source. If a small time
delay is desired between when the two channels sample
the analog inputs, CLKA and CLKB can be driven by two
different signals. If this delay exceeds 1ns, the performance
of the part may degrade. CLKA and CLKB should not be
driven by asynchronous signals.
Figures 12 and 13 show alternatives for converting a
differential clock to the single-ended CLK input. The use
of a transformer provides no incremental contribution
to phase noise. The LVDS or PECL to CMOS translators
provide little degradation below 70MHz, but at 140MHz will
degrade the SNR compared to the transformer solution.
The nature of the received signals also has a large bearing on how much SNR degradation will be experienced.
For high crest factor signals such as WCDMA or OFDM,
where the nominal power level must be at least 6dB to
8dB below full scale, the use of these translators will have
a lesser impact.
ETC1-1T
CLK
LTC2282
5pF-30pF
DIFFERENTIAL
CLOCK
INPUT
2282 F13
0.1μF
FERRITE
BEAD
VCM
Figure 13. LVDS or PECL CLK Drive Using a Transformer
The transformer in the example may be terminated with
the appropriate termination for the signaling in use. The
use of a transformer with a 1:4 impedance ratio may be
desirable in cases where lower voltage differential signals
are considered. The center tap may be bypassed to ground
through a capacitor close to the ADC if the differential
signals originate on a different plane. The use of a capacitor at the input may result in peaking, and depending
on transmission line length may require a 10Ω to 20Ω
ohm series resistor to act as both a low pass filter for
high frequency noise that may be induced into the clock
line by neighboring digital signals, as well as a damping
mechanism for reflections.
Maximum and Minimum Conversion Rates
The maximum conversion rate for the LTC2282 is
105Msps. The lower limit of the LTC2282 sample rate is
determined by droop of the sample-and-hold circuits. The
pipelined architecture of this ADC relies on storing analog
2282fb
16
LTC2282
APPLICATIONS INFORMATION
signals on small valued capacitors. Junction leakage will
discharge the capacitors. The specified minimum operating frequency for the LTC2282 is 1Msps.
Clock Duty Cycle Stabilizer
An optional clock duty cycle stabilizer circuit ensures
high performance even if the input clock has a non
50% duty cycle. Using the clock duty cycle stabilizer is
recommended for most applications. To use the clock
duty cycle stabilizer, the MODE pin should be connected
to 1/3VDD or 2/3VDD using external resistors.
This circuit uses the rising edge of the CLK pin to sample
the analog input. The falling edge of CLK is ignored and
the internal falling edge is generated by a phase-locked
loop. The input clock duty cycle can vary from 40% to
60% and the clock duty cycle stabilizer will maintain a
constant 50% internal duty cycle. If the clock is turned off
for a long period of time, the duty cycle stabilizer circuit
will require a hundred clock cycles for the PLL to lock
onto the input clock.
For applications where the sample rate needs to be changed
quickly, the clock duty cycle stabilizer can be disabled. If
the duty cycle stabilizer is disabled, care should be taken to
make the sampling clock have a 50% (±5%) duty cycle.
DIGITAL OUTPUTS
Digital Output Buffers
Figure 14 shows an equivalent circuit for a single output buffer. Each buffer is powered by OVDD and OGND,
isolated from the ADC power and ground. The additional
N-channel transistor in the output driver allows operation down to low voltages. The internal resistor in series
with the output makes the output appear as 50Ω to external circuitry and may eliminate the need for external
damping resistors.
As with all high speed/high resolution converters, the
digital output loading can affect the performance. The
digital outputs of the LTC2282 should drive a minimal
capacitive load to avoid possible interaction between the
digital outputs and sensitive input circuitry. For full speed
operation the capacitive load should be kept under 10pF.
Lower OVDD voltages will also help reduce interference
from the digital outputs.
LTC2282
OVDD
VDD
0.5V
TO 3.6V
VDD
0.1μF
OVDD
DATA
FROM
LATCH
PREDRIVER
LOGIC
43Ω
TYPICAL
DATA
OUTPUT
OE
OGND
Table 1 shows the relationship between the analog input
voltage, the digital data bits and the overflow bit.
2282 F14
Figure 14. Digital Output Buffer
Table 1. Output Codes vs Input Voltage
AIN+ – AIN–
(2V Range)
OF
D11 – D0
(Offset Binary)
D11 – D0
(2’s Complement)
>+1.000000V
+0.999512V
+0.999024V
1
0
0
1111 1111 1111
1111 1111 1111
1111 1111 1110
0111 1111 1111
0111 1111 1111
0111 1111 1110
+0.000488V
0.000000V
–0.000488V
–0.000976V
0
0
0
0
1000 0000 0001
1000 0000 0000
0111 1111 1111
0111 1111 1110
0000 0000 0001
0000 0000 0000
1111 1111 1111
1111 1111 1110
–0.999512V
–1.000000V
<–1.000000V
0
0
1
0000 0000 0001
0000 0000 0000
0000 0000 0000
1000 0000 0001
1000 0000 0000
1000 0000 0000
Data Format
Using the MODE pin, the LTC2282 parallel digital output
can be selected for offset binary or 2’s complement format. Connecting MODE to GND or 1/3VDD selects offset
binary output format. Connecting MODE to 2/3VDD or
VDD selects 2’s complement output format. An external
resistor divider can be used to set the 1/3VDD or 2/3VDD
logic values. Table 2 shows the logic states for the
MODE pin.
2282fb
17
LTC2282
APPLICATIONS INFORMATION
Table 2. MODE Pin Function
Output Format
Clock Duty
Cycle Stabilizer
0
Offset Binary
Off
1/3VDD
Offset Binary
On
2/3VDD
2’s Complement
On
VDD
2’s Complement
Off
MODE Pin
Overflow Bit
When OF outputs a logic high the converter is either overranged or underranged.
Output Driver Power
Separate output power and ground pins allow the output
drivers to be isolated from the analog circuitry. The power
supply for the digital output buffers, OVDD, should be tied to the
same power supply as for the logic being driven. For example,
if the converter is driving a DSP powered by a 1.8V supply,
then OVDD should be tied to that same 1.8V supply.
OVDD can be powered with any voltage from 500mV up to
3.6V. OGND can be powered with any voltage from GND
up to 1V and must be less than OVDD. The logic outputs
will swing between OGND and OVDD.
Output Enable
The outputs may be disabled with the output enable pin,
OE. OE high disables all data outputs including OF. The
data access and bus relinquish times are too slow to
allow the outputs to be enabled and disabled during full
speed operation. The output Hi-Z state is intended for use
during long periods of inactivity. Channels A and B have
independent output enable pins (OEA, OEB).
Sleep and Nap Modes
The converter may be placed in shutdown or nap modes
to conserve power. Connecting SHDN to GND results in
normal operation. Connecting SHDN to VDD and OE to VDD
results in sleep mode, which powers down all circuitry,
including the reference, and typically dissipates 1mW.
When exiting sleep mode, it will take milliseconds for the
output data to become valid because the reference capacitors have to recharge and stabilize. Connecting SHDN to
VDD and OE to GND results in nap mode, which typically
dissipates 30mW. In nap mode, the on-chip reference circuit
is kept on, so that recovery from nap mode is faster than
that from sleep mode, typically taking 100 clock cycles. In
both sleep and nap modes, all digital outputs are disabled
and enter the Hi-Z state.
Channels A and B have independent SHDN pins (SHDNA,
SHDNB). Channel A is controlled by SHDNA and OEA, and
channel B is controlled by SHDNB and OEB. The nap, sleep
and output enable modes of the two channels are completely
independent, so it is possible to have one channel operating
while the other channel is in nap or sleep mode.
Digital Output Multiplexer
The digital outputs of the LTC2282 can be multiplexed onto
a single data bus if the sample rate is 80Msps, or less. The
MUX pin is a digital input that swaps the two data busses.
If MUX is high, channel A comes out on DA0-DA11, OFA;
channel B comes out on DB0-DB11, OFB. If MUX is low,
the output busses are swapped and channel A comes out
on DB0-DB11, OFB; channel B comes out on DA0-DA11,
OFA. To multiplex both channels onto a single output bus,
connect MUX, CLKA and CLKB together (see the Timing
Diagram for the multiplexed mode). The multiplexed data
is available on either data bus—the unused data bus can
be disabled with its OE pin.
Grounding and Bypassing
The LTC2282 requires a printed circuit board with a clean,
unbroken ground plane. A multilayer board with an internal
ground plane is recommended. Layout for the printed
circuit board should ensure that digital and analog signal
lines are separated as much as possible. In particular, care
should be taken not to run any digital track alongside an
analog signal track or underneath the ADC.
2282fb
18
LTC2282
APPLICATIONS INFORMATION
High quality ceramic bypass capacitors should be used
at the VDD, OVDD, VCM, REFH, and REFL pins. Bypass
capacitors must be located as close to the pins as possible. Of particular importance is the 0.1μF capacitor
between REFH and REFL. This capacitor should be placed
as close to the device as possible (1.5mm or less). A size
0402 ceramic capacitor is recommended. The large 2.2μF
capacitor between REFH and REFL can be somewhat
further away. The traces connecting the pins and bypass
capacitors must be kept short and should be made as
wide as possible.
The LTC2282 differential inputs should run parallel
and close to each other. The input traces should be as
short as possible to minimize capacitance and to minimize
noise pickup.
Heat Transfer
Most of the heat generated by the LTC2282 is transferred
from the die through the bottom-side exposed pad and
package leads onto the printed circuit board. For good
electrical and thermal performance, the exposed pad
should be soldered to a large grounded pad on the PC
board. It is critical that all ground pins are connected to
a ground plane of sufficient area.
Clock Sources for Undersampling
Undersampling raises the bar on the clock source and the
higher the input frequency, the greater the sensitivity to
clock jitter or phase noise. A clock source that degrades
SNR of a full-scale signal by 1dB at 70MHz will degrade
SNR by 3dB at 140MHz, and 4.5dB at 190MHz.
In cases where absolute clock frequency accuracy is
relatively unimportant and only a single ADC is required,
a 3V canned oscillator from vendors such as Saronix
or Vectron can be placed close to the ADC and simply
connected directly to the ADC. If there is any distance to
the ADC, some source termination to reduce ringing that
may occur even over a fraction of an inch is advisable.
You must not allow the clock to overshoot the supplies or
performance will suffer. Do not filter the clock signal with
a narrow band filter unless you have a sinusoidal clock
source, as the rise and fall time artifacts present in typical
digital clock signals will be translated into phase noise.
The lowest phase noise oscillators have single-ended
sinusoidal outputs, and for these devices the use of a filter
close to the ADC may be beneficial. This filter should be
close to the ADC to both reduce roundtrip reflection times,
as well as reduce the susceptibility of the traces between
the filter and the ADC. If you are sensitive to close-in phase
noise, the power supply for oscillators and any buffers
must be very stable, or propagation delay variation with
supply will translate into phase noise. Even though these
clock sources may be regarded as digital devices, do not
operate them on a digital supply. If your clock is also used
to drive digital devices such as an FPGA, you should locate
the oscillator, and any clock fan-out devices close to the
ADC, and give the routing to the ADC precedence. The
clock signals to the FPGA should have series termination
at the source to prevent high frequency noise from the
FPGA disturbing the substrate of the clock fan-out device.
If you use an FPGA as a programmable divider, you must
re-time the signal using the original oscillator, and the retiming flip-flop as well as the oscillator should be close to
the ADC, and powered with a very quiet supply.
For cases where there are multiple ADCs, or where the
clock source originates some distance away, differential
clock distribution is advisable. This is advisable both from
the perspective of EMI, but also to avoid receiving noise
from digital sources both radiated, as well as propagated in
the waveguides that exist between the layers of multilayer
PCBs. The differential pairs must be close together, and
distanced from other signals. The differential pair should
be guarded on both sides with copper distanced at least
3X the distance between the traces, and grounded with
vias no more than 1/4 inch apart.
2282fb
19
R14
49.9Ω
C19
0.1μF
5
ASSEMBLY TYPE
DC851A-U
DC851A-V
2
U1
LTC2282IUP
LTC2282IUP
+
4
2
2
1
R8
51
•3
VDD
5
4
•
R9
*
R7
24.9Ω
2
1
E5
PWR
GND
E3
VDD
3V
C34
0.1μF
GND
VCMB
VDD
VCC
AINA+
AINA–
REFHA
REFHA
REFLA
REFLA
VDD
CLKA
CLKB
VDD
REFLB
REFLB
REFHB
REFHB
AINB–
AINB+
VCM
VDD
4
2
C47
0.1μF
C48
0.1μF
EXT REF
5
6
3
1
C2
2.2μF
C27
0.1μF
JP3 SENSE
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
VDD
C1
0.1μF
INPUT FREQUENCY
fIN < 70MHz
fIN > 70MHz
C41
0.1μF
VDD
C21
0.1μF
C11
0.1μF
C4
0.1μF
VCMB
8
6
4
2
E2
EXT
REF B
1/3VDD
T1, T2
ETC1-1T
ETC1-1-13
C40
0.1μF
R24
*
C31
*
C23 1μF
VDD
2/3VDD
C20
2.2μF
C18 1μF
R22
24.9Ω
7
5
3
1
C10
2.2μF
C9 1μF
R3
1k
R2
1k
R1
1k
C13 1μF
R20
24.9Ω
R18
*
R39
OPT
VDD
C6
*
C6, C31
12pF
8pF
VDD
•3
R23
51
T2
*
C17
0.1μF
R32
OPT
C44
0.1μF
R6
24.9Ω
R5
*
C8
0.1μF
VDD
C14
0.1μF
C36
4.7μF
VCMB
C33
0.1μF
C29
0.1μF
R16
33Ω
C22
0.1μF
•
T1
*
R5, R9, R18, R24
24.9Ω
12.4Ω
C45
100μF
6.3V
OPT
J4
R17
ANALOG OPT
INPUT B
4
5
4
VCMA
C7
0.1μF
5
VCM
EXT REF
5
6
3
1
C3
0.1μF
U6 3
NC7SVU04
4
C15
0.1μF
C12
4.7μF
6.3V
R15 3
1k
U3
NC7SVU04
2
R10
1k
*VERSION TABLE
J3
CLOCK
INPUT
VDD
L1
BEAD
J2
ANALOG R4
INPUT A OPT
VCMA
E1
EXT
REF A
VDD
VDD
JP2 SENSEA
VDD
64
63
62
61
60
59
58
57
56
55
54
53
52
51
50
49
LTC2282
C37
10μF
6.3V
C35
0.1μF
C28
2.2μF
R26
100k
R25
105k
U8
LT1763
C25
0.1μF
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
C38
0.01μF
VDD
VCC
C5
0.1μF
1
8
IN
OUT
2
7
ADJ GND
3
6
GND GND
4
5
BYP SHDN
VCC
VCC
DA5
DA4
DA3
DA2
DA1
DA0
NC
NC
OFB
DB11
DB10
DB9
DB8
DB7
DB6
DB5
GND
VDD
SENSEA
VCMA
MODE
SHDNA
OEA
OFA
DA11
DA10
DA9
DA8
DA7
DA6
OGND
OVDD
GND
VDD
SENSEB
VCMB
MUX
SHDNB
OEB
NC
NC
DB0
DB1
DB2
DB3
DB4
OGND
OVDD
20
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
JP1 MODE
C39
1μF
OE
T/R
GND
OE
GND
T/R
74VCX245BQX
19
VCC
11
A7
B7
12
A6
B6
13
A5
B5
14
A4
B4
15
U11
B3
A3
16
A2
B2
17
A1
B1
18
B0
A0
20
VCC
74VCX245BQX
19
VCC
11
A7
B7
12
A6
B6
13
A5
B5
14
A4
B4
15
U10
B3
A3
16
A2
B2
17
A1
B1
18
A0
B0
20
VCC
74VCX245BQX
10
1
2
3
4
5
6
7
9
8
10
4
E4
GND
U4
NC7SV86P5X
RN8B 33Ω
RN8A 33Ω
RN7D 33Ω
RN7B 33Ω
RN7C 33Ω
RN7A 33Ω
RN6D 33Ω
2
1
RN6C 33Ω
RN6B 33Ω
RN6A 33Ω
RN5B 33Ω
RN5C 33Ω
RN5D 33Ω
RN5A 33Ω
3
4
5
6
7
9
8
20
VCC
9
11
A7
B7
12
8
A6
B6
13
7
A5
B5
14
6
A4
B4
15
5
U9
B3
A3
16
4
A2
B2
17
3
A1
B1
18
2
B0
A0
1
T/R
19
10
OE GND
VCC
74VCX245BQX
20
VCC
11
9
A7
B7
8
12
A6
B6
7
13
A5
B5
6
14
A4
B4
5
15
U2
B3
A3
16
4
A2
B2
17
3
A1
B1
18
2
A0
B0
1
T/R
19
10
OE GND
VCC
3
5
VCC
1
2
RN4C 33Ω
RN4B 33Ω
RN4A 33Ω
RN3D 33Ω
RN3C 33Ω
RN2D 33Ω
RN3A 33Ω
RN3B 33Ω
RN2B 33Ω
RN2C 33Ω
RN1C 33Ω
RN1D 33Ω
RN2A 33Ω
RN1A 33Ω
RN1B 33Ω
C24
0.1μF
R35
100k
15
16
25
27
29
31
33
35
26
28
30
32
34
36
61
1
A0
2
A1
3
A2
4
A3
C46
0.1μF
R34
4.7k
100
98
94
96
92
84
86
88
90
76
78
80
82
72
74
68
70
8
VCC
7
WP
6
SCL
5
SDA
R36
4.99k
99
97
93
95
91
83
85
87
89
75
77
79
81
71
73
67
69
63
65
59
62
64
66
55
57
60
53
54
56
58
45
47
49
51
46
48
50
52
37
39
41
43
23
24
38
40
42
44
21
22
17
19
7
9
11
13
8
10
12
14
18
20
1
3
5
U5
24LC025
J1
EDGE-CON-100
2
4
6
ENABLE
SDA
VCCIN
SCL
VSS
R38
R37
4.99k
R33
4.7k
VCC
2282 AI01
SDA
SCL
VCCIN
VSS
LTC2282
APPLICATIONS INFORMATION
2282fb
LTC2282
APPLICATIONS INFORMATION
Silkscreen Top
Top Side
2282fb
21
LTC2282
APPLICATIONS INFORMATION
Inner Layer 2 GND
Inner Layer 3 Power
Bottom Side
2282fb
22
LTC2282
PACKAGE DESCRIPTION
UP Package
64-Lead Plastic QFN (9mm × 9mm)
(Reference LTC DWG # 05-08-1705)
0.70 ±0.05
7.15 ±0.05
8.10 ±0.05 9.50 ±0.05
(4 SIDES)
PACKAGE OUTLINE
0.25 ±0.05
0.50 BSC
RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS
9 .00 ± 0.10
(4 SIDES)
0.75 ± 0.05
R = 0.115
TYP
63 64
0.40 ± 0.10
PIN 1 TOP MARK
(SEE NOTE 5)
1
2
PIN 1
CHAMFER
7.15 ± 0.10
(4-SIDES)
(UP64) QFN 1003
0.25 ± 0.05
0.200 REF
0.00 – 0.05
NOTE:
1. DRAWING CONFORMS TO JEDEC PACKAGE OUTLINE MO-220 VARIATION WNJR-5
2. ALL DIMENSIONS ARE IN MILLIMETERS
3. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE
MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.20mm ON ANY SIDE, IF PRESENT
4. EXPOSED PAD SHALL BE SOLDER PLATED
5. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION ON THE TOP AND BOTTOM OF PACKAGE
6. DRAWING NOT TO SCALE
0.50 BSC
BOTTOM VIEW—EXPOSED PAD
2282fb
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
23
LTC2282
RELATED PARTS
PART NUMBER
DESCRIPTION
LTC2220
12-Bit, 170Msps ADC
COMMENTS
890mW, 67.5dB SNR, 9mm × 9mm QFN Package
LTC2221
12-Bit, 135Msps ADC
630mW, 67.5dB SNR, 9mm × 9mm QFN Package
LTC2222
12-Bit, 105Msps ADC
475mW, 67.9dB SNR, 7mm × 7mm QFN Package
LTC2223
12-Bit, 80Msps ADC
366mW, 68dB SNR, 7mm × 7mm QFN Package
630mW, 67.5dB SNR, 7mm × 7mm QFN Package
LTC2224
12-Bit, 135Msps ADC
LTC2225
12-Bit, 10Msps ADC
60mW, 71.4dB SNR, 5mm × 5mm QFN Package
LTC2226
12-Bit, 25Msps ADC
75mW, 71.4dB SNR, 5mm × 5mm QFN Package
LTC2227
12-Bit, 40Msps ADC
120mW, 71.4dB SNR, 5mm × 5mm QFN Package
LTC2228
12-Bit, 65Msps ADC
205mW, 71.3dB SNR, 5mm × 5mm QFN Package
890mW, 67.5dB SNR, 9mm × 9mm QFN Package
LTC2230
10-Bit, 170Msps ADC
LTC2231
10-Bit, 135Msps ADC
630mW, 67.5dB SNR, 9mm × 9mm QFN Package
LTC2232
10-Bit, 105Msps ADC
475mW, 61.3dB SNR, 7mm × 7mm QFN Package
LTC2233
10-Bit, 80Msps ADC
366mW, 61.3dB SNR, 7mm × 7mm QFN Package
LTC2245
14-Bit, 10Msps ADC
60mW, 74.4dB SNR, 5mm × 5mm QFN Package
75mW, 74.5dB SNR, 5mm × 5mm QFN Package
LTC2246
14-Bit, 25Msps ADC
LTC2247
14-Bit, 40Msps ADC
120mW, 74.4dB SNR, 5mm × 5mm QFN Package
LTC2248
14-Bit, 65Msps ADC
205mW, 74.3dB SNR, 5mm × 5mm QFN Package
LTC2249
14-Bit, 80Msps ADC
222mW, 73dB SNR, 5mm × 5mm QFN Package
LTC2254
14-Bit, 105Msps ADC
320mW, 72.5dB SNR, 5mm × 5mm QFN Package
395mW, 72.4dB SNR, 5mm × 5mm QFN Package
LTC2255
14-Bit, 125Msps ADC
LTC2280
10-Bit, Dual, 105Msps ADC
540mW, 61.6dB SNR, 9mm × 9mm QFN Package
LTC2284
14-Bit, Dual, 105Msps ADC
540mW, 72.4dB SNR, 9mm × 9mm QFN Package
LTC2286
10-Bit, Dual, 25Msps ADC
150mW, 61.8dB SNR, 9mm × 9mm QFN Package
LTC2287
10-Bit, Dual, 40Msps ADC
235mW, 61.8dB SNR, 9mm × 9mm QFN Package
LTC2288
10-Bit, Dual, 65Msps ADC
400mW, 61.8dB SNR, 9mm × 9mm QFN Package
LTC2289
10-Bit, Dual, 80Msps ADC
422mW, 61dB SNR, 9mm × 9mm QFN Package
LTC2290
12-Bit, Dual, 10Msps ADC
120mW, 71.3dB SNR, 9mm × 9mm QFN Package
LTC2291
12-Bit, Dual, 25Msps ADC
150mW, 71.4dB SNR, 9mm × 9mm QFN Package
LTC2292
12-Bit, Dual, 40Msps ADC
235mW, 71.4dB SNR, 9mm × 9mm QFN Package
400mW, 71.3dB SNR, 9mm × 9mm QFN Package
LTC2293
12-Bit, Dual, 65Msps ADC
LTC2294
12-Bit, Dual, 80Msps ADC
422mW, 70.6dB SNR, 9mm × 9mm QFN Package
LTC2295
14-Bit, Dual, 10Msps ADC
120mW, 74.4dB SNR, 9mm × 9mm QFN Package
LTC2296
14-Bit, Dual, 25Msps ADC
150mW, 74.5dB SNR, 9mm × 9mm QFN Package
LTC2297
14-Bit, Dual, 40Msps ADC
235mW, 74.4dB SNR, 9mm × 9mm QFN Package
LTC2298
14-Bit, Dual, 65Msps ADC
400mW, 74.3dB SNR, 9mm × 9mm QFN Package
LTC2299
14-Bit, Dual, 80Msps ADC
444mW, 73dB SNR, 9mm × 9mm QFN Package
2282fb
24 Linear Technology Corporation
LT 0308 REV B • PRINTED IN USA
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900 ● FAX: (408) 434-0507
●
www.linear.com
© LINEAR TECHNOLOGY CORPORATION 2005